Method and Apparatus for Forming Metal Reinforcing

ABSTRACT

An apparatus for forming a metal reinforcing bar incorporates a multi stage forming line forming a termination on an enlarged end portion of the bar. The termination is shaped to form part of an interlock to connect the bar to another member. In one form, the forming line includes a forming station where the termination is at least partially formed by a forging process.

TECHNICAL FIELD

The present invention relates to reinforcement for concrete or other cemetitious construction and more specifically to a method and apparatus for forming such reinforcing.

BACKGROUND OF THE INVENTION

In the construction industry, structures (such as walls, floors, slabs, columns and the like) of concrete are produced by positioning reinforcing such as steel reinforcing bars in a region where concrete is then poured to produce the structure. The bars are supported in desired positions and often there is a need to join lengths of bars to each other to ensure that the reinforcing not only is correctly positioned, but is able to transmit load across the coupling so that the bars can accommodate a large part or even their full axial capacity in either tension or compression.

Co-pending International application filed by the Applicant entitled “A Reinforcing Bar” discloses reinforcing incorporating a termination that extends along an end portion of the bar and that is arranged to form part of an interlock to connect the bar to another member. Whilst a reinforcing bar of this design has substantial practical benefit, it is necessary to be able to manufacture the bar inexpensively and reliably to enable it to be commercially acceptable to the market.

SUMMARY OF THE INVENTION

According to a first aspect, there is provided a method of forming a metal reinforcing bar comprising the step of forming a termination on an enlarged end portion of the bar, the termination being shaped to form part of an interlock to connect the bar to another member.

In a particular form, the end portion is heated before forming the termination and in one form, the termination is at least partially formed by a forging process, which is typically either a hot or warm forging process. Further, in one form, the cooling of the end portion is controlled so that the heating or the end portion does not substantially alter the material properties of the bar. In one form, the reinforcing bar is formed from steel and the end portion is heated to a temperature to allow forging (for example above 1000° C. for a hot forge or above 700° C. for a warm forge) and, after forging, the end portion is allowed to cool to a temperature of less than 460° C. under substantially ambient conditions. In another form, where the bar is tempered, the heated end may undergo an initial quenching process to reduce the steel temperature rapidly (say to 600° C.) and then allow the end portion to cool under ambient temperature conditions to less than 460° C.

An advantage of at least one embodiment of the method of forming the bar described above is that the termination is made as an integral part of bar. As such the strength of the termination can be properly matched to the strength of the bar. A major problem with prior art couplers that use separate components is the fact that the reinforcing bar may vary in strength (for example nominal 500 MPa may vary from 500 MPa to an allowed top strength of 650 MPa). This means that couplers may be mismatched with extremely strong bars so the couplers need to be made to accommodate this possible mismatch. This can have attendant problems as it may reduce the ductile properties of the coupler itself by providing a coupler of higher strength than required. The integral nature of the termination to the shaft obviates this mismatch and allows for ductility and strength of the coupling to be correctly matched to the bar shaft.

Further, by forming the termination from an enlarged end, the strength at the resultant coupling using the termination may be greater than the bar being joined. In one form, the coupling has a strength of approximately 110% of the strength of the bar although as will be appreciated this could be varied by varying the dimensions of the various components in the termination.

In a particular embodiment, a preform of the termination is formed by the forging operation; and the finished termination is formed in a subsequent milling operation of the preform. This arrangement has the advantage of allowing a more angular profile on the termination than may otherwise be reliably provided solely by a forging operation. However, it is to be appreciated that depending on the profile of the termination, it may be shaped without requiring a milling process.

In one form, the method uses reinforcing bar having a substantially constant cross section as feed stock. In that arrangement, the method further comprises the steps of enlarging an end portion of the bar and forming the termination on the enlarged end portion. In one form this step of enlarging the end portion is part of the forging operation and is undertaken whilst the end portion is heated.

In one form, the termination is shaped to incorporate an engagement face incorporating locking formations thereon. A engagement face which is profiled in this shape is disclosed in the Applicant's corresponding International application entitled “A Reinforcing Bar”, the contents of which are herein incorporated by cross reference.

In yet a further aspect, the invention provides a forming apparatus for reinforcing bars, the apparatus comprising a multi stage forming line arranged to receive the reinforcing bars and to form a termination on an enlarged end of the reinforcing bars, the termination being shaped to form part of an interlock to connect the bar to another member.

In one form, the forming line incorporates a heating stage having at least one heating station arranged to heat the end portion of the reinforcing bar; and a forging stage having at least one forging station arranged to at least partially shape the termination on the heated end portion by a forging process. In a particular arrangement, the forging station incorporates a plurality of cooperating dies that are operative to shape the heated end portion.

In one form, the forging stage further comprises a trimming station arranged to trim the at least partially shaped termination following processing of the end portion by the forging station.

In a particular embodiment, the forging stage further comprises an upset station arranged to enlarge the heated end portion of the reinforcing bars prior to processing of those end portions by the forging station. In one form, the upset station incorporates at least one forging punch operative to enlarge the heated end portion.

In a particular embodiment, the forming line further comprises a cooling stage subsequent to the forging stage, the cooling stage being arranged to control the cooling of the heated end portion so that the heating of the end portions of the bars do not substantially alter the material properties of the bars. In one form, where the bar is tempered steel, the heating stage is operative to heat the end portions of the reinforcing bars to a temperature suitable for hot or warm forging and wherein the cooling stage is operative to allow quench cooling of the end portions to a first temperature and than to a second lesser temperature under substantially ambient conditions.

In a particular embodiment, a preform of the termination is formed in the forging stage and the forming line further comprises a milling stage including at least one milling station operative to finish the termination by milling of the preform. Typically, the milling stage is subsequent to the cooling stage.

In a particular arrangement, at least one of the stations is moveable into and out of register with the end portions of the reinforcing bars. In this way the feeding of the reinforcing bars through the forming line may be simplified as they need only progress in one direction along those stages of the forming line.

In a particular arrangement, the apparatus further comprises a feed assembly operative to feed individual reinforcing bars through the forming line. In a particular arrangement, the apparatus is operative to receive reinforcing bars of different diameters and the rate of feed of the feed assembly changes along at least some of the stages depending on the diameter of the bar.

In a particular form, the forming line is arranged to form terminations on opposite ends of the reinforcing bars. In one form, at least one of the stages incorporates first and second spaced apart stations that are operative to engage with the opposite ends of the reinforcing bars simultaneously. In one form, the spacing between the first and second stations of the at least one stage is able to be varied to allow for forming of reinforcing bars of different lengths. In another form, the feed assembly is operative to rotate the reinforcing bars to enable a station of at least one of the stages to process the respective opposite ends of the reinforcing bars sequentially.

Typically a controller is provided that is operative to control operation of the feed assembly and the various stages of the forming line. Further a quality assurance process may be provided as part of a finishing stage to check the dimensions and the integrity of the reinforcing bar terminations. This stage may utilise imaging equipment to enable an image of the bar to be assessed against a pre-stored criteria.

In further aspects, the invention relates to a reinforcing bar production facility and to a method of producing reinforcing bar. These aspects incorporate the methods and/or apparatus described above to enable a fully integrated system of manufacture of the bar with the terminations.

BRIEF DESCRIPTION OF THE DRAWINGS

It is convenient to hereinafter describe embodiments of the present invention with reference to the accompanying drawings. It is to be appreciated however that the particularity of the drawings and the related description is to be understood as not limiting the preceding broad description of the invention.

In the drawings:

FIG. 1 is a partial perspective view of a reinforcing bar showing a shaped termination at one end of the bar;

FIG. 2 is a perspective view of a coupling incorporating a pair of reinforcing bars of FIG. 1;

FIG. 3 is a cross-sectional view of the coupling of FIG. 2;

FIG. 4 is a schematic plan view of a forming apparatus for reinforcing bars;

FIG. 5 is a detailed view of a forging punch in a first upset station of the apparatus of FIG. 4;

FIG. 6 is a detailed view of a forging punch in a second upset station of the apparatus of FIG. 4;

FIG. 7 is a cross-sectional view of forging dies of the apparatus of FIG. 4;

FIG. 8 is a cross-section of trim dies of the apparatus of FIG. 4;

FIG. 9 is a graph representing the cooling period for reinforcing bars of various diameter; and

FIG. 10 is a schematic block view of a reinforcing production facility including the reinforcing apparatus of FIG. 4.

DETAILED DESCRIPTION OF THE DRAWINGS

Turning firstly to FIG. 1, a partial view of a reinforcing bar 10 is shown. The bar 10, which is typically made from steel, incorporates a shaft 11 which extends along the majority of the length of the bar 10. Whilst only a small portion of the shaft 11 is shown, it is to be appreciated that this shaft may extend for many metres. These bars are made in continuous lengths and are cut to size depending on the requirements of a particular job. Furthermore, for convenience, the shaft 11 as shown is plain. Again, it is to be appreciated that the shaft may include ribbing, and such bar is commonly referred to as deformed bar.

The reinforcing bar 10 further includes a termination 12 which extends along an end portion of the bar to the terminal end 13 of the reinforcing bar 10. Whilst not shown, typically the bar would also include a similar termination at its other end 25. In the illustrated form, the termination 12 is integrally formed with the shaft 11 and is enlarged as compared to that shaft (i.e. it extends radially outwardly from a central axis CL of the reinforcing bar a greater distance than the shaft). A transition zone 14 is present between the shaft 11 and the enlarged termination 12.

The termination 12 includes an engagement face 15 which extends along a length of the bar 10 and projects outwardly therefrom. This engagement face 15 is profiled to include locking formations which enables the bar 10 to be coupled to another bar or other object to form an interlock as will be discussed in more detail below. The locking formations in the illustrated form comprise a plurality of spaced apart upstands 16, 17, 18 and 19 and a plurality of recesses 20, 21, 22 and 23. The majority of these recesses 21, 22 and 23 extend between adjacent ones of the upstands (16, 17, 18 and 19). A proximal one of the recesses 20 extends between a hub portion 24 of the termination and the most proximal upstand 16.

The termination is configured as a part cylinder having a diameter which is greater than the axis of the shaft 11. Furthermore, the engagement face 15 is formed effectively as a “cut out” from that cylindrical termination. However, it is to be appreciated that whist the engagement face 15 may be considered as a cut out portion, it is not limited to such a method of manufacturing as the termination may be formed by a forging operation of the like into its final shape without the need for any substantial removal of material. Such a process is described in detail below.

Turning now to FIGS. 2 and 3, a coupling 50 is disclosed which is formed from interconnection of the termination 12 of one reinforcing bar with an identical termination of another like bar. For convenience in the following description of the coupling 50, one reinforcing bar is designated using superscript I whereas the other reinforcing bar includes superscript II with associated features given like designations.

The coupling 50 is formed by interconnecting the terminations 12 ^(I) and 12 ^(II) to form an interlock 51 with the upstands of one termination interfitting within a corresponding recesses of the other termination. The interlock extends along an axis (designated A-A) which, in the illustrated form, is coaxial with the central axis of the respective reinforcing bars 10 ^(I) and 10 ^(II). Furthermore, once the terminations 12 ^(I) and 12 ^(II) are interconnected along their engagement faces 15 ^(I) and 15 ^(II) the exterior surface of the termination forms a complete cylinder (which in the illustrated form is a circular cylinder) having a diameter which is greater than the diameter of the respective shafts 11 ^(I) and 11 ^(II).

The coupling 50 also includes a retaining device 52 which is arranged to prevent separation of the terminations. In the illustrated form, the retaining device 51 is in the form of a sleeve, typically a metal sleeve having an internal bore which is just slightly larger than the exterior diameter of the cylinder formed by the interconnected terminations. In this way the sleeve can slide over the lapping terminations and is typically retained in place by a wire tie or the like.

Turning to FIGS. 4 to 8, a multistage forming apparatus 100 is disclosed which is operative in formation of the reinforcing bar 10 as previously described. Specifically, the forming apparatus is designed to receive reinforcing bars of constant diameter and to form the shaped terminations 12 on respective opposite ends of the bars. As will be discussed in more detail below, the forming apparatus 100 is able to cater for reinforcing bars of different diameters, typically in the range of 16 mm to 36 mm as well as to cater for differing bar lengths (typically from 1.5 m to 8 m).

The apparatus 100 includes five principal stages; being a heating stage 101; a forging stage 102; a cooling stage 103; a machining stage 104 and a finishing stage 105. The apparatus further comprises a feed assembly 106 which is arranged to control the movement of the reinforcing bars through the apparatus 100.

The feed assembly 106 takes the reinforcing bars from an in-feed mechanism 107 through to a discharge mechanism 108. During this movement the feed assembly 106 presents the ends (13,25) of the reinforcing bars 10 in a position where each station of each of the five stages may undertake the required processing of the respective bars 10.

At the in-feed mechanism 107 the reinforcing bars, which are of a pre-specified length of substantially constant diameter, are disposed on to a table and are fed into a magazine. A feeder system then indexes one bar at a time to be received onto a heating conveyor 109, which forms part of the feed assembly 106.

The heating conveyor 109 includes continuous chains 110 on which locating and carrying brackets (not shown) are mounted to receive the bars 10 so as to keep them at a discrete distances apart and in a parallel relationship. The conveyor 109 is able to accommodate bar lengths typically ranging from 1.5 metres to 8 metres.

The heating stage 101 is in the form of a pair of three stage induction coil heating stations 111 and 112. These heating stations are disposed opposing one another so as to be able to engage with and heat opposite ends of respective bars simultaneously. To cater for reinforcing bars of different length, one induction heating station 111 is fixed whilst the other 112 is mounted to allow movement of the stations to vary the gap therebetween so as to accommodate bars of different length.

The heating conveyor 109 presents the respective ends 13,25 of the bars 10 at the heating stations 111 and 112. The stations are movable inwards and outwards so as to be able to move in and out of register with the respective bar ends. As the heating stations are 3-stage coil inductors, the stations are caused to register three times with each bar, with the bar moving into each of the three coils. The heating conveyor 109 is arranged to index the bar in line with each of these three coils with this indexing occurring when the stations are moved out of register with the respective bar ends 13, 25.

In one form, where the reinforcing bars are made from steel, the heating stage is arranged to heat the end portions of the bar to in excess of 1000° C. In one application this temperature is set at 1150° C. However it will be appreciated that the temperature may vary depending on the metallurgy of the bar or the type of forging process that is used.

On exiting the heating stage 101 the reinforcing bars are then conveyed to the forming stage 102 which includes three discrete stations, being upset station 113, forging station 114, and trim station 115.

As best illustrated in FIG. 4, the forging stage 102 only includes one set of stations which are disposed adjacent the heating station 111. To enable each end 13,25 of the respective reinforcing bars to be processed through the forging stage 102, the feed assembly 106 includes a robot assembly 116 having a robot arm 117 which is arranged to pick up individual bars off the heating conveyor 109 and place one end of those bars into register with each of the forging stations 113, 114, 115. The robot assembly 116 is also able to invert the bar to enable the other end of the reinforcing bars to be moved into register with each of those stations. Therefore in the forging stage 102 the ends are processed sequentially rather than simultaneously as in the heating stage 101.

In the upset station 113, the respective ends of the reinforcing bar are enlarged. The upset station includes a first and second forging punch (118, 119) as best illustrated in FIGS. 5 and 6. These forging punches are forced over the heated end portions of the bars to cause the bar ends to swell. A two stage operation is used so that less force is required as compared to what would be required if it was a single pass system. During this upsetting process the bar is held in position by the robot arm 117.

Once the end portion of the reinforcing bar is enlarged, it is then moved into register with the forging station 114. The forging station 114 includes first and second dies 120, 121 which cooperate to shape the enlarged end portion to form a preform 30 of the termination 12. That preform 30 is close to the final shape of the termination 12 and includes the general shape of the engagement face 15 and the upstands 16,17,18 and 19 and recesses 20, 21, 22 and 23. However, the transitions between the upstands and the recesses are not fully defined and as material needs to be removed to make these transitions more angular. This processing step is done in the milling stage 104 as will be discussed below.

After the end portion has been shaped by the forging station 114 it is then passed to the trim station 115 where excess flashing is removed which extends about the perimeter of the preform 30. This is achieved again by a set of cooperating dies 122, 123 as best illustrated in the FIG. 8. Once the trimming has been completed the forging stage for that end of the bar is completed. The bar is then inverted and the other end is processed by the respective stations 113, 114, 115 of the forging stage 102.

It is to be appreciated that the forging station could be configured in a similar manner to the heating stage where two sets of stations are located at opposite ends of the bars so that the forging of the ends is conducted simultaneously rather than sequentially. The main advantage of using only one set of stations for the forging stage 102 as illustrated is that it reduces the overall cost of the forming line 100 without any significant loss in processing time of the bars 10.

Once both ends of the bars have been shaped by the forging stage 102 the bars then enter the cooling stage 103. A cooling conveyor 124 forms part of the feed assembly 106 and is of similar construction as the heater conveyor 109 including two sets of endless chains 110.

The cooling stage 103 is set up to control the cooling of the end portions of the reinforcing bars 10 so that the properties of the end portions are not substantially affected by the heating of those bars. In this way, the end portions of the bars retain the same material properties as the bar shafts 11.

The cooling stage 103 includes three parts. A first part comprises quenching stations 125, 126. In a similar design as in the heating stage 101 one of the quenching stations is fixed whilst the other 126 is movable so as to cater for reinforcing bars of separate length. In use, many reinforcing bars are formed from tempered steel and the purpose of the quenching station is to return the temper to the end portions. This is achieved by quickly cooling the surface of the bars by forcing water over the heated bar surface. During this quenching process typically the surface temperature of the bar reduces to approximately 600° C. although again it is to be appreciated that the specific temperatures could vary depending on the construction of the bar. Further in some instances where non-tempered steel is used for the feed stock, this quenching part may be bypassed.

After leaving the quenching stage the reinforcing bars are then moved along the cooling conveyor 124 for sufficient time to allow the temperature of the bar to reduce to a lower threshold (typically in the order of 460° C.) under ambient temperature conditions. The length of the cooling time to achieve this lower threshold will vary depending on the thickness of the bar. In tests conducted by the applicant it is found that for steel reinforcing bars ranging between 16 mm to 35 mm, the cooling time is between 300 and 500 seconds. This is represented in the graph in FIG. 9.

Once the bar has reached this lower threshold temperature it can then be cooled rapidly without affecting the properties of the steel. In the illustrated form, the cooling stage 103 includes a pair of water coolers 127,128 which pass a stream of water over the bar ends to more quickly reduce the temperature of the end portions then would otherwise occur if left to cool under ambient temperature conditions.

Following the cooling stage 103, the bars 10 are then passed to the milling stage 104 where a pair of milling stations 129,130 machine the preform 30 of the terminations into their finished stage. Again one station 130 is movable relative to the other to cater for differing bar lengths. The milling stations 129,130 include a set of gang milling cutters which traverse over the preform 30 whilst they are hydraulically clamped in a stationary position. The milling operation is done in several roughing and finishing operations with the bars being indexed several times through the milling stations and are clamped on different parts of the finished profile to facilitate complete machining of the whole termination.

Following the milling stage 104, the bars are then moved to a finishing stage 105 which includes finish stations 131,132 to clean the surface of the terminations and then to final QA and inspection stations 133,134. These QA stations 133,134 consist of an electronic comparative system using digital cameras. The stations check the finished profile against reference data held in memory and give off a signal to the operating system if a termination is outside the scope of the specification. These stations may also include a self-diagnostic mode allowing the operator to take corrective action.

Once the bars have passed through the QA system, they are then discharged on to the discharge mechanism 108 so that they can be bundled and then strapped for transport.

An advantage of the apparatus as disclosed is that it may be fully automated. In this regard the various stations are typically operated under hydraulic power which in turn is operated under a central controller. In particular in certain stages of the operation, most notably during the heating and cooling stages, the times that the bar may need to remain in those stages may vary depending on the diameter of the bar. This can be achieved by controlling the feed assembly 106 and in particular the speed of the respective conveyors 109,124.

The apparatus 100 can be fully integrated into a production facility for reinforcing bars. As will be appreciated by those skilled in the art, reinforcing bars are typically made in continuous lengths which are then cut into stock lengths where they are stockpiled. For any particular job, an order is placed which typically specifies both the length and the diameter of the bar. This order is fulfilled by cutting lengths of bar from the stockpile. The apparatus 100 can be integrated into this process. Whilst previously the bars would be cut to their exact size, when using the apparatus 100 they are made slightly larger to take into account the termination formation process undertaken by the apparatus 100. These lengths are then fed into the apparatus 100 which is set based on both the length of the bars as well as their diameter (under operation of the controller) and are then fed through the forming line. Accordingly, the reinforcing bars with these terminations can be manufactured in the same facility as standard reinforcing bar and in that way can be offered as an optional stock item which is fulfilled in a manner consistent with standard reinforcing bar.

FIG. 10 illustrates a production facility outlining the major components of manufacturing the bar in accordance with the above. This facility 500 includes a bar forming line 501 which manufactures the bar in continuous lengths, a storage facility 502 where the bar is stored in stock lengths, and the apparatus 100 for forming the terminations on the end of the bars as described above.

In the claims which follow and in the preceding description of the invention, except where the context requires otherwise due to express language or necessary implication, the word “comprise” or variations such as “comprises” or “comprising” is used in an inclusive sense, i.e. to specify the presence of the stated features but not to preclude the presence or addition of further features in various embodiments of the invention.

Variations and modifications may be made to the parts previously described without departing from the spirit or ambit of the invention. 

1: A method of forming a metal reinforcing bar comprising forming a termination on an enlarged end portion of the bar, the termination being shaped to form part of an interlock to connect the bar to another member.
 2. The method according to claim 1, wherein said end portion is heated before forming said termination.
 3. The method according to claim 2, wherein said termination is at least partially formed by a forging process.
 4. The method according to claim 2, further comprising controlling the cooling of said end portion so that the heating of said end portion does not substantially alter the material properties of said bar.
 5. The method according to claim 4, wherein said reinforcing bar is formed from tempered steel and wherein the end portion is heated to a temperature suitable for forging and is quench cooled to a first temperature and is then cooled to a lower second temperature under substantially ambient conditions.
 6. The method according to claim 2, further comprising: forming a preform of said termination by said forging operation; and forming the finished termination by milling of said preform.
 7. The method according to claim 1, further comprising: providing a reinforcing bar having a substantially constant cross section; enlarging an end portion of said bar; and forming said termination on said enlarged end.
 8. The method according to claim 7, wherein said end portion is heated before being enlarged.
 9. The method according to claim 8, wherein said end portion is enlarged by a forging process.
 10. The method according to claim 1, wherein the termination is shaped to incorporate an engagement face incorporating locking formations thereon.
 11. A forming apparatus for reinforcing bars, the apparatus comprising a multi stage forming line arranged to receive the reinforcing bars and to form a termination on an enlarged end of the reinforcing bars, the termination being shaped to form part of an interlock to connect the bar to another member.
 12. The forming apparatus according to claim 11, wherein the forming line incorporates a heating stage having at least one heating station arranged to heat the end portion of the reinforcing bar; and a forging stage having at least one forging station arranged to at least partially shape the termination on the heated end portion by a forging process.
 13. The forming apparatus according to claim 12, wherein the forging station incorporates a plurality of cooperating dies that are operative to shape the heated end portion.
 14. The forming apparatus according to claim 12, wherein the forging stage further comprises a trimming station arranged to trim the at least partially shaped termination following processing of the end portion by the forging station.
 15. The forming apparatus according to claim 12, wherein said forging stage further comprises an upset station arranged to enlarge the heated end portion of the reinforcing bars prior to processing of those end portions by said forging station.
 16. The forming apparatus according to claim 15, wherein said upset station incorporates at least one forging punch operative to enlarge said heated end portion.
 17. The forming apparatus according to claim 12, wherein the forming line further comprises a cooling stage subsequent to said forging stage, said cooling stage being arranged to control the cooling of the heated end portion so that the heating of the end portions of the bars do not substantially alter the material properties of said bars.
 18. The forming apparatus according to claim 17, wherein the heating stage is operative to heat the end portion of the reinforcing bar to a temperature suitable for forging and wherein the cooling stage is operative to quench cool the end portions to a first temperature and then to allow cooling of the end portions to a second temperature under substantially ambient conditions.
 19. The forming apparatus according to claim 12, wherein a preform of said termination is formed in said forging stage and wherein the forming line further comprises a milling stage including at least one milling station operative to finish the termination by milling of said preform.
 20. The forming apparatus according to claim 19, wherein the forming line further comprises a cooling stage subsequent to said forging stage, said cooling stage being arranged to control the cooling of the heated end portion and wherein the milling stage is subsequent to said cooling stage.
 21. The forming apparatus according to claim 12, wherein at least one of the stations is moveable into and out of register with said end portions of the reinforcing bars.
 22. The forming apparatus according to claim 11, further comprising a feed assembly operative to feed individual reinforcing bars through said forming line.
 23. The forming apparatus according to claim 22, wherein the apparatus is operative to receive reinforcing bars of different diameter and wherein the rate of feed of the feed assembly changes along at least some of the stages depending on the diameter of the bar.
 24. The forming apparatus according to claim 12, wherein the forming line is arranged to form terminations on opposite ends of the reinforcing bars.
 25. The forming apparatus according to claim 24, wherein at least one of the stages incorporates first and second spaced apart stations that are operative to engage with the opposite ends of the reinforcing bars simultaneously.
 26. The forming apparatus according to claim 25, wherein the spacing between the first and second stations of said at least one stage is able to be varied to allow for forming of reinforcing bars of different lengths.
 27. The forming apparatus according to claim 26, wherein the feed assembly is operative to rotate the reinforcing bars to enable a said station of at least one of the stages to process the respective opposite ends of the reinforcing bars.
 28. The forming apparatus according to claim 11, further comprising a controller operative to control operation of feed assembly and the various stages of said forming line.
 29. A reinforcing bar production facility comprising a bar producing apparatus to produce reinforcing bar, the bar having lengths of substantially constant diameter; and a forming apparatus according to claim 11, wherein said forming apparatus receives discrete lengths of the reinforcing bar formed by said bar producing apparatus.
 30. The reinforcing bar production facility according to claim 29, wherein the bar producing apparatus is operative to form reinforcing bar in continuous lengths.
 31. A method of producing a reinforcing bar comprising the steps of: producing a reinforcing bar having a substantially constant diameter; cutting the reinforcing bar into discrete lengths; forming an enlarged end on at least one end of the lengths of the reinforcing bar; and forming a termination on the enlarged end portion of the bar, the termination being shaped to form part of an interlock to connect the bar to another member.
 32. The method according to claim 31, wherein the reinforcing bar is cut into discrete lengths in response to an order for the reinforcing bar. 